Computational and physical simulation of fluid flow inside a beam blank continuous casting mold

Abstract

The main features of the flow field inside a beam blank continuous casting mold have been assessed through mathematical and physical modeling techniques. Experimental techniques such as particle dispersion through addition of dye and particle image velocimetry have been used in a physical model of the mold to assess the flow pattern. Different combinations of nozzle geometry and throughput have been employed and the experimental results have been analyzed. In the case of two tubular nozzles, which should ensure good thermal and flow symmetry, six vortices were observed in the mold, two near the web and two in each of the flanges. Increasing the flow rate of the fluid from 100L/min to 150L/min leads to a change from 0.74m to 0.84m in the jet penetration depth. However even a 67% increase of the nozzle cross section did not affect this parameter significantly. Experiments with one single tubular nozzle (53.2mm inside diameter) were also carried out and the resulting flow asymmetry has been characterized. The difference in the fluid velocities at the filets could lead to unequal solid shell growth. The depth of jet penetration is larger than mold nominal length (0.8m). Fluid flow structure as determined by PIV measurements and CFD simulations show a good agreement.